report on capitol hill housing’s unreinforced …...b. recommendation: wall anchorage would likely...
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REPORT ON CAPITOL HILL HOUSING’S UNREINFORCED MASONRY BUILDINGS
DATE: July 31, 2018
TO: Leadership Team
FROM: Dylan Locati
REGARDING: CHH’s Unreinforced Masonry (“URM”) Buildings
SUMMARY: The Seattle City Council is currently contemplating adopting an ordinance that would mandate owners of
“Unreinforced Masonry” (URM; see Addendum A for description) buildings to make seismic retrofits in order to make
them more earthquake resilient. Although the ordinance is currently in draft form and anticipated to be brought to a vote
in 2019, the Seattle Department of Constructions and Inspections (SDCI) has done outreach to building owners and
compiled a list of properties preliminary research has identified as being possible URM buildings. Capitol Hill Housing has
received letters from the City for ten of our properties that may be subject to the ordinance’s retrofit requirements.
ACTIONS TAKEN: CHH has engaged the structural engineering services of Swenson Say Fagét (SSF) to review each of the
ten properties. Additionally, CHH tasked SSF to evaluate five other properties not identified by the City but which share
similar characteristics with URM buildings (e.g. brick masonry façade). The following is a summary of their findings:
Building Identified by City Vulnerability Engineer’s Findings
Berneva No n/a Not URM; exempt
Bremer Yes High Not URM; exempt(1)
Brewster Yes Medium URM; mandated retrofits
Devonshire No n/a Not URM; exempt
Fleming Yes Medium URM; mandated retrofits
Fredonia No n/a Not URM; exempt
Helen V No n/a Not URM; exempt
Larned Yes Medium URM; mandated retrofits
Lincoln Court Yes Medium Not URM; exempt
Melrose Yes Medium URM; mandated retrofits
Oleta No n/a Not URM; exempt
Park Hill Yes Medium Not URM; exempt
Silvian Yes Medium URM; mandated retrofits
Villa Yes High URM; mandated retrofits
El Nor(2) Yes Medium TBD
(1) Although Bremer was found to not technically be a URM building, SSF strongly recommends it be retrofitted as one. Bremer will be included
in the “CHH Portfolio 1” project and will have earthquake protection retrofits included.
(2) El Nor evaluation and potential retrofit is being led by the Property Development team as part of the resyndication process.
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NEXT STEPS: The Policy Committee advising the City Council on the draft ordinance has proposed the following timeline
for implementing URM retrofits:
*Year 0 is the year in which City Council passes ordinance and initiates program (anticipated 2019)
Total time allotted for policy implementation ranges from 7 – 13 years based off the vulnerability of the building, as
determined by the Committee. Vulnerability categories are determined by factors such as the number of residents living
at the building, it’s primary use, and soil conditions. CHH has two properties classified as “High”: the Bremer and the Villa.
SSF has determined that the Bremer is in fact not a URM bearing wall building and can thus be removed from the City’s
list, however, they strongly recommend it be retrofitted as if it were a URM building. Property Development has included
the Bremer in the “Capitol Hill Portfolio 1” project in order to finance seismic upgrades and other improvements.
The remaining eight buildings on the City’s list are classified as “Medium vulnerability”; the lowest priority category. As
noted in the table on page 1, two of these buildings (Park Hill and Lincoln Court) have been determined to be non-URM
buildings. CHH’s next steps will be to send the engineer’s findings to the City in order to remove Park Hill, Lincoln Court,
and the Bremer from the URM list.
CHH will review the engineer’s recommendations for confirmed URM buildings (see Addendum B for summary and
detailed recommendations) and begin crafting action plans and establishing timelines for retrofit work. Additionally, CHH
will review the engineer’s recommendations for retrofits at several non-URM buildings (Bremer, Lincoln Court, and Park
Hill). The preliminary nature of the ordinance leaves the financing aspect uncertain and will likely alter CHH’s project
timing once those details become known.
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CONCLUSION: CHH is dedicated to providing safe and affordable communities. Moreover, CHH has been recognized for
its work in preserving structures that capture the character and design of prior eras. Unfortunately, many of these
buildings do not meet current seismic code standards. We believe that our commitment to providing safe housing has
been demonstrated by prior safety-enhancing retrofits that we have made as well as the proactive approach we have
taken in confronting this challenge.
ADDENDUM A
“Unreinforced Masonry” buildings are buildings where load bearing walls, non-load bearing walls or other structures, such
as chimneys, are made of brick, cinderblock, tiles, adobe or other masonry material that is not braced by reinforcing
material, such as rebar in a concrete or cinderblock. URM structures are vulnerable to collapse in an earthquake. One
problem is that most mortar used to hold bricks together is not strong enough. Additionally, masonry elements may "peel"
from the building, and fall onto occupants or passersby outside. In Seattle, most of these buildings were built prior to
1945.
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ADDENDUM B
CHH Unreinforced Masonry Building Summary Matrix
: URM Bolts+ Qualifies
: Non-URM
Retrofit Brewster Fleming Larned(1) Melrose Silvian(2) Villa Bremer Lincoln Court Park Hill El Nor(3)
URM Shear Walls X X
Wall Anchorage X X X X X X
Force Transfer to Shear Walls X X X X X X X
Wall Bracing X
Diaphragms X X
Wall Height-to-Thickness Ratio X X
Parapets X X X
Chimneys X
Moment Frames X
Girder-Column Connections X
Settlement Remediation X
Veneer Re-Anchor X
Estimated Cost Range $ $$ $$ $$ $$$ $ $$ $ $
1) Partially qualifies; has vertical irregularity (soft or weak first story) on the east and west elevations and the east and west walls at first
floor have 0% qualifying piers (minimum of 40% to qualify)
2) Partially qualifies; cross walls do not extend above the attic to roof diaphragm and North South and East Walls are 31% solid (minimum
of 40% to qualify)
3) El Nor evaluation and potential retrofit is being headed by Property Development department as part of the resyndication process
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: Non-URM Brick Masonry Buildings
Retrofit Helen V Oleta Fredonia Berneva Devonshire
URM Shear Walls
Wall Anchorage
Force Transfer to Shear Walls
Wall Bracing
Diaphragms
Wall Height-to-Thickness Ratio
Parapets
Chimneys
Moment Frames
Girder-Column Connections
Settlement Remediation
Veneer Re-Anchor
Estimated Cost Range n/a n/a n/a n/a n/a
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The following retrofit details have been extracted from the SSF evaluation reports and can be found on
Integratec (under Documents � select “Consultant Reports” under Main Type � select “URM report”
under Secondary Type
Bremer (included in Property Development “CH Portfolio 1”
Project)
Non-URM
(should be retrofitted as if URM)
Recommended retrofits (in order of priority):
1. Parapet and chimney bracing
a. Finding: The 1992 drawings included details for bracing of the roof parapet walls. During
our site visit, no evidence of the parapet bracing installation was observed. The work was
noted on plans as “Deferred until roofing replacement” and presumably was never
completed. URM parapets are a known falling hazard during a seismic event and should
be braced if they project above the roof level more than 1.5 times their thickness. All
parapets at the building exceed this height limitation. The unreinforced masonry
chimneys extending above the roof are a known hazard during a seismic event. Chimneys
should be braced when their height exceeds twice the smallest dimension. The chimney
at the Bremer Apartments does not exceed the maximum recommended height-to-
thickness ratio.
b. Recommendation: We recommend installing parapet bracing around the perimeter of
the roof. Parapet bracing may consist of steel angle braces spaced at 48” on center
connecting the parapet to the roof deck. Typical bracing anchorage includes epoxy
grouted threaded rods at the URM wall and blocking installed in the roof joists to support
the out-of-plane forces. Though the chimney does not exceed the maximum height to
thickness ratio, we recommend bracing it at the same height as the adjacent parapet.
2. Force Transfer to Shear Walls
a. Finding: There does not appear to be a connection to transfer in-plane shear forces from
the floor and roof diaphragms to the exterior walls.
b. Recommendation: To transfer the seismic forces to the URM shear walls, we recommend
installing threaded rod shear bolts through existing blocking and joists, where they are
perpendicular to the walls. Wall anchor rods, described above, provide shear transfer
between the walls and blocking (or joists, where parallel to the wall) at 4’ on-center. We
also recommend nailing the perimeter of the diaphragm to the blocking/joists with 16d
box nails @ 4” on-center.
3. Wall Anchorage
a. Finding: The exterior URM walls depend on attachment to the floor and roof diaphragms
for lateral out- of-plane bracing. Wall anchorage was not observed at the roof or floor
levels, and no evidence of anchorage was observed from the exterior of the building. Non-
conforming wall anchorage is typical for this type and age of construction.
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b. Recommendation: Wall anchorage would likely consist of premanufactured steel
anchors, Simpson LTT19 or equivalent, spaced at 4 feet on center, and attached to the
floor joists and walls with ¾" diameter threaded rod and rosettes. Anchorage should be
placed at all elevated diaphragm levels on all elevations.
4. Wall Height-to-Thickness Ratio
a. Finding: Walls exceeding the recommended height to thickness ratios are susceptible to
collapse in a seismic event. Due to the wood framed bearing walls adjacent to the exterior
URM walls, the URM walls are thinner than a typical building of similar size. The exterior
walls are only two wythe thick and exceed the height to thickness ratio between the third
floor and the roof by a factor of 2.0.
b. Recommendation: Because of the wood bearing wall construction, we believe the risk
associated with out-of-plane wall collapse is lesser than compared with a typical URM
bearing wall building. It is worth having a conversation with the SDCI regarding exceptions
to the wall thickness restrictions. If it the walls are determined to be out of compliance,
then we recommend reinforcing the third-floor walls with vertical strong back posts at six
feet on center. Strong backs would consist of HSS tubes or heavy gage steel studs
anchored to the wall with epoxy anchors and a braced to the floor and roof diaphragms.
Brewster
URM
Qualifies for Bolts+ Retrofit
Recommended retrofits (in order of priority):
1. Force Transfer to Shear Walls
a. Finding: Connections to transfer in-plane shear forces from the floor and roof diaphragms
to the exterior walls occurs only at the North and South elevations at the 3rd floor. The
10d panel edge nailing transfers lateral loads from the new plywood overlay into 2x wood
ledgers connected to the exterior URM walls with the out-of-plane anchorage thru bolts
which double as shear anchors. These connections, however, do not provide sufficient
capacity to meet the strength criteria of the proposed ordinance.
b. Recommendation: To transfer the seismic forces to the URM shear walls, we recommend
installing threaded rod shear bolts at 48 inches on center at locations of existing bent
plate anchors, which occur at the East and West walls at the 1st, 2nd, 3rd, and roof levels
and at the South wall at the roof level. We also recommend nailing the perimeter of the
diaphragm to the blocking/joists with 16d box nails at 4 inches on-center at all wall and
floor locations.
2. Wall Anchorage
a. Finding: The exterior URM walls depend on attachment to the floor and roof diaphragms
for lateral out- of-plane bracing. Wall anchorage is present at the roof and all floor levels.
Wall anchorage at the North and South elevations at the 3rd floor and at the North
elevation at the roof consists of ¾” diameter thru bolts at 48 inches on center with
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rosettes at the exterior face and interior MTT28 straps connected to perpendicular floor
or roof joists. Wall anchorage at all other locations consists of ¾” diameter thru bolts at
48 inches on center with rosettes at the exterior face and interior ¼” steel bent plates
nailed to two or three bays of blocking between joists. According to our analysis the bent
plate anchors do not meet the anchor strength criteria of the proposed ordinance, so only
the wall anchorage at the North and South elevations at the 3rd floor and the North
elevation at the roof conforms with the minimum requirements for Bolts Plus retrofit.
b. Recommendation: Nonconforming bent plate anchors may be retrofitted by providing
new steel plates between the existing bent plates and thru bolt heads.
Fleming
URM
Qualifies for Bolts+ Retrofit
Recommended retrofits (in order of priority):
1. Parapet and chimney bracing
a. Finding: The URM parapets have not been braced for out-of-plane forces. URM parapets
are a known falling hazard during a seismic event and should be braced if they project
above the roof level more than 1.5 times their thickness. All parapets at the building
exceed this height limitation. The unreinforced masonry chimneys extending above the
roof are a known hazard during a seismic event. Chimney should be braced when their
height exceeds twice the smallest dimension. The chimney at the Fleming does not
exceed the maximum recommended height-to-thickness ratio.
b. Recommendation: We recommend installing parapet bracing around the perimeter of
the roof. Parapet bracing may consist of steel angle braces spaced at 48” on center
connection the parapet to the roof deck. Typical bracing anchorage includes epoxy
grouted threaded rods at the URM wall and blocking installed in the roof joists to support
the out-of-plane forces. Though the chimney does not exceed the maximum height-to-
thickness ratio, we recommend bracing it at the same height as the adjacent parapet.
2. Wall Anchorage
a. Finding: The exterior URM walls depend on attachment to the floor and roof diaphragm
for lateral out-of-plane bracing. Wall anchorage was not observed at the roof or floor
levels, and no evidence of anchorage was observed from the exterior of the building. Non-
conforming wall anchorage is typical for this type and age of construction.
b. Recommendation: Wall anchorage would likely consist of premanufactured steel
anchors, Simpson LTT19 or equivalent, spaced at 4’ on center, and attached to the floor
joists and walls with ¾” diameter threaded rod and rosettes. Anchorage should be placed
at all elevated diaphragm levels on all elevations.
3. Force Transfer to Shear Walls
a. Finding: There does not appear to be a connection to transfer in-plane shear forces from
the floor and roof diaphragms to the exterior walls.
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b. Recommendation: To transfer the seismic forces to the URM shear walls, we recommend
installing threaded rod shear bolts through existing blocking and joists, where they are
perpendicular to the walls. Wall anchor rods, described above, provide shear transfer
between the walls and blocking (or joists, where parallel to the wall) at 4’ on-center. We
also recommend nailing the perimeter of the diaphragm to the blocking/joists with 16d
box nails @ 4” on-center.
Larned
URM
Partially Qualifies for Bolts+ Retrofit
Recommended retrofits (in order of priority):
1. Wall Anchorage
a. Finding: The exterior URM walls depend on attachment to the floor and roof diaphragms
for lateral out- of-plane bracing. Retrofit wall anchorage was installed at all levels using
rosettes and Simpson LTT20B tension ties on top of the floor diaphragm. However, the
anchorage is of insufficient strength to transfer the anchor forces to the diaphragm.
b. Recommendation: We recommend supplementing the existing anchors with additional
epoxy grouted anchors and tension ties. These anchors would be installed in tandem with
shear transfer anchors, below in Item 2.
2. Force Transfer to Shear Walls
a. Finding: The 1991 renovation plans do not show a connection to transfer in-plane shear
forces from the floor and roof diaphragms to the exterior walls.
b. Recommendation: We recommend installing ¾” threaded rod epoxy anchors at 4’ on
center into the joist adjacent the exterior wall where parallel, or into continuous blocking
where joists are perpendicular to the wall.
3. Parapets
a. Finding: Parapets were either braced or rebuilt in 1991 and the installed bracing meets
the maximum spacing requirements. The parapet on the north elevation was rebuilt with
reinforced concrete masonry units (CMU). The rebuilt parapets are cantilevered from the
URM wall below and still present a falling hazard to the sidewalk below.
b. Recommendation: We recommend installing parapet bracing at 6’ on center along the
north parapet. Braces would be constructed of 4”x4”x1/4” angles, similar to the existing
braces on the east and west elevations.
4. Moment Frames
a. Finding: At the open storefronts, steel moment resisting frames were added in 1991 to
resist lateral seismic forces. Subsequent code changes have affected the design and
detailing of moment frames, and the existing frames do not meet current seismic
requirements. Initial analysis of the frames found the columns overstressed by a factor of
2.2. The beam column connections and foundations were also found to be deficient.
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b. Recommendation: We recommend opening a discussion with the city on what is
considered an acceptable amount of overstress for steel moment frames from earlier
retrofits. In the event that the calculated DCR is beyond what is deemed acceptable by
the city, we recommend further evaluation of the frames to determine if they can be
brought up to current code. If they cannot be improved, then replacement with braced
frames or concrete shear walls is recommended.
5. Diaphragms
a. Finding: Long span diaphragms often experience large lateral deflections and diaphragm
shear demands. Large deflections can result in increased damage or collapse of elements
laterally supported by the diaphragm. Excessive diaphragm shear demands will cause
damage and reduced stiffness in the diaphragm. The area cut out of the diaphragm at
the third floor and roof amplifies diaphragm stresses around the opening.
b. Recommendation: Diaphragm improvements are not required for Bolts Plus due to the
cross walls and plywood sheathing being previously added to the roof. However, we
recommend plywood sheathing in areas around the light well to prevent tearing of the
diaphragm.
6. Girder-column connections
a. Finding: A positive connection between beams and columns is required to prevent
columns from shifting off their supports during a seismic event. In the basement, positive
girder-girder connections were made with continuity straps, but no positive connection
was made between the girders and the column.
b. Recommendation: We recommend installing steel angle clips, fastened with lag screws,
where girders are supported by interior columns.
*Extra Notes: SSF concluded that portions of Larned’s 1991 retrofit do not comply with the current life
safety standard, however, they believe the retrofit meets the spirit of the pending ordinance and that it
has an improved margin against seismic collapse. Based off this opinion, SSF believes the City may be open
to negotiating the extent of additional retrofit measures.
Lincoln Court
Non-URM
Recommended issues to investigate/retrofit:
1. Building Settlement
a. Finding: During the site visit we observed severely sloping and uneven floors in the second
and third floor hallways on the north side of the building. This portion of the building,
clouded in Figure 5 in the report, is over an unexcavated crawlspace with wood post and
beam framing supported by a concrete pier block foundation system. We observed
several large notches in the wood beams at the column supports. Horizontal shear failures
were visible in the beams at these notches and are shown in Figure 4. Other support
columns were observed with significant tilt out of plumb. The onsite manager also
reported that the north side of the building had severe water infiltration issues prior to a
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building envelope renovation in 2009. Water infiltration over time may have saturated
the soils, reducing their bearing capacity and allowing the post and beam system to settle
excessively. Undersized foundation pier blocks can exacerbate the settlement issue on
compromised soils. We did observe a new roof drain system that directed all collected
water away from the building and into the adjacent parking lot storm drain
b. Recommendation: We recommend further investigation of the footing conditions,
including a geotechnical report to establish the allowable bearing capacity of the soils.
Remediation of the settlement would likely include new concrete foundations and steel
posts supporting the existing beams. Where the existing beams are split due to excessive
notching, we recommend replacement or repair with steel side plates. Repairing the
beams, columns and foundations should limit future settlement of the building, however
it may not be feasible to raise existing floors back to their original level condition.
Melrose
URM
Qualifies for Bolts+ Retrofit
Recommended retrofits (in order of priority):
1. Wall Anchorage
a. Finding: The exterior URM walls depend on attachment to the floor and roof diaphragms
for lateral out- of-plane bracing. Wall anchorage consisting of Simpson MTT28B anchors
and ¾” threaded rod through bolted with 6” diameter rosettes spaced at 4’ on-center is
present at all levels. Wall anchorage at the North and South elevations is anchored to
existing joists which develop the wall loads into the existing diaphragms. Wall anchorage
at the East and West Elevations is anchored in the two bays of 2x blocking between
existing joists. Two bays of blocking is not adequate to develop the wall anchorage forces
into the diaphragm. In addition, the plans have conflicting information regarding anchors
installed at the north end of the east wall. The elevation shows no anchors due to the
presence of an adjacent building on the property line. The structural drawings call out
anchors with rosettes. It is possible anchors were installed by drilling and epoxying, rather
than with rosettes, but this could not be confirmed.
b. Recommendation: We recommend installing additional bays of blocking at the east and
west walls to develop the anchors into the floor diaphragm, and we recommend verifying
the presence of anchors at the east wall.
2. Force Transfer to Shear Walls
a. Finding: Connections are required to transfer in-plane shear forces from the floor and
roof diaphragms to the exterior shear walls. Although new blocking was shown in the
1990 drawings, the connection does not provide sufficient capacity to meet the strength
criteria of the proposed ordinance. However, the rosettes visible on the outside of the
building indicate that the out-of-plane anchors may be installed between existing joists,
rather than above the joists as shown in the existing drawings. If this is the case, the out-
of-plane bolts could provide adequate shear anchor strength.
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b. Recommendation: We recommend investigating at least one location each, at the 2nd
floor, 3rd or 4th floor, and roof at the east/west, and north/south walls. Six locations total.
The investigation would determine the actual construction of the wall anchorage. The
first step would be to accurately measure the location of the rosettes to determine if they
occur between floor joists. If the rosettes are located between the joists, we recommend
opening the veiling finishes to determine the as-built condition of the anchors. If the as-
built condition of the anchors do not have capacity to meet ordinance requirements, or
rosettes occur above or below the joists, we recommend installing ¾” threaded rod at
48” on-center, through the existing blocking between joists at all floors.
3. Wall height-to-thickness ratio
a. Finding: Walls exceeding the recommended height to thickness ratios are susceptible to
collapse in a seismic event. The exterior East and West walls at the 4th floor do not comply
with the proposed ordinance.
b. Recommendation: Provide strongback walls consisting of wood stud, or light gauge steel
furring at the east and west walls at the 4th floor. Studs walls are typically 6” deep and
with top and bottom plates screwed to the floor, and light gauge clips anchored to the
masonry with 3/8” diameter epoxy bolts at 24” on-center, vertically.
Park Hill
Non-URM
Recommended issues to investigate/retrofit:
1. Bugling Brick Veneer
a. Finding: We did find evidence of bulging brick veneer on the south façade. The
displacement was most pronounced at the stair, with a horizontal offset from plumb
reaching 1” or more in some areas.
b. Recommendation: We recommend having the veneer re-anchored to the building, in
addition, we recommend installing a strongback in the stair well to brace the wall out-of-
plane.
Silvian
URM
Partially Qualifies for Bolts+ Retrofit
Recommended retrofits (in order of priority):
1. Diaphragms
a. Finding: Long span diaphragms often experience large lateral deflections and diaphragm
shear demands. Large deflections can result in increased damage or collapse of elements
laterally supported by the diaphragm. Excessive diaphragm shear demands will cause
damage and reduced stiffness in the diaphragm. The roof diaphragm spans exceed the
maximum 24’ span for straight sheathed diaphragms without crosswalls.
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b. Recommendation: We recommend ½” plywood sheathing on the roof, with 8d nails at 4”
o.c/ at panel edges. Improvement to the floor diaphragms is not required because of the
interior crosswalls.
2. Wall Anchorage
a. Finding: The exterior URM walls depend on attachment to the floor and roof diaphragm
for lateral out-of-plane bracing. Retrofit wall anchorage was installed at all levels using
rosettes and light-gage steel straps with bearing plates on top of the floor diaphragm.
However, the anchorage is of insufficient strength to transfer the anchor forces to the
diaphragm.
b. Recommendation: We recommend reinforcing the existing wall anchorage by replacing
the bearing plate with steel angle integrated with the shear transfer angle described
below in item 3.
3. Force Transfer to Shear Walls
a. Finding: The 1982 renovation plans do not show a connection to transfer in-plane shear
forces from the floor and roof diaphragms to the exterior walls. The floor diaphragm has
been nailed to blocking around the perimeter, however, there is no load path from the
blocking to the URM wall.
b. Recommendation: To transfer the seismic forces to the URM shear walls, we recommend
installing a continuous steel 4”x4”x1/2” angle around the perimeter of the diaphragm on
each level. The existing rosette bolts can be reused to anchor the angle to the wall. Shear
transfer from the angle to the diaphragm can be accomplished by providing ¼” SDS screws
through the bottom leg of the angle to the existing perimeter blocking. The shear transfer
angle also functions as a drag strut to collect load to the new braced frames.
4. URM Shear Walls
a. Finding: The URM walls are inadequate for resisting lateral seismic forces, largely due to
the tall, narrow wall piers created by the multi-story wood infill framing or bay windows.
The north, south and east elevations do not meet the minimum solid wall pier
requirement. The west wall does not have any multi-story openings and it does meet the
minimum 40% solid pier requirement.
b. Recommendation: We recommend steel braced frames as a supplemental lateral system
at the north, south, and east elevations, from the basement to the roof. Potential braced
frame configurations and locations are shown in the schematic sketches in the report
(Appendix B). New braced frames will also include steel angle or channel drag struts at
the perimeter of the building to transfer load to the frames from elsewhere in the
diaphragm. Foundations for the braced frames would likely consist of a concrete grade
beam supported by micropile deep foundations. Due to the spalling bricks and generally
deteriorated condition of the mortar joints, we recommend having the exterior URM
walls evaluated by a masonry contractor for tuck pointing and repairs.
5. Diaphragms (Life Safety Upgrade)
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a. Finding: The floor diaphragms in the building benefit from the interior partition walls, aka
crosswalls, which assist in dampening diaphragm deflection, however, the diagonal
straight sheathing is overstressed by a factor of 2.6.
b. Recommendation: We recommend re-sheathing the 1982 interior gypsum shear walls
with plywood and adding new longitudinal and transverse shear walls. Proposed shear
walls are shown on the schematic plans in the report (Appendix B).
6. West elevation lateral system (Life Safety Upgrade)
a. Finding: The west URM wall does not have any multi-story openings and it does meet the
minimum 40% solid pier requirement for Bolts Plus. However, further analysis of the wall
indicates that it is overstressed by a factor of 3.5, which does not meet the Life Safety
criteria.
b. Recommendation: We recommend an additional steel braced frame as a supplemental
lateral system on the west elevation, from the basement to the roof. Including a braced
frame will bring the west elevations to the same level of compliance as the rest of the
building. Drags struts and foundations will be similar as those described in item 1.
Villa
URM
Qualifies for Bolts+ Retrofit
Recommended retrofits (in order of priority):
1. Braced frame retrofit at the south wall ground floor (open storefront)
a. Finding: There is an open storefront on the south side of the building, which was
retrofitted in 1998 with two chevron braced frames. According to our calculations, the
retrofitted frames fail to meet current standards by a factor of two or more.
b. Recommendation: We recommend steel braced frames be replaces or renovated to meet
current earthquake code requirements. The retrofit would likely require enhancing or
replacing the top and drag strut connection, and strengthening or replacing the existing
grade beam.
2. In-plane shear anchors
a. Finding: The 1998 renovation plans do not show a connection to transfer in-plane shear
forces from the floor and roof diaphragms to the exterior walls. The floor diaphragm has
been nailed to blocking around the perimeter, however, there is no load path from the
blocking to the URM wall.
b. Recommendation: To transfer the seismic forces to the URM shear walls, we recommend
installing anchor bolts through the existing blocking. Anchors are typically ¾” diameter
and spaced at 4’ on-center.
*Extra Notes: The 1998 retrofit installed frames to the open storefront, however, the frames do no not
meet current seismic requirements. SSF is of the opinion that it may be possible to seek the City’s approval
to allow CHH to keep the current system and enhance the connections and retrofit the foundation to meet
Page 15
current requirements. Absent City approval, or if it is not technically feasible to retrofit the current system,
SSF believes the frames will need to be replaced with a standard braced frame.
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